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Whenever I see some source packages or binaries which are compressed with GZip I wonder if there are still reasons to favor gz over xz (excluding time travel to 2000), the savings of the LZMA compression algorithm are substantial and decompressions isn't magnitudes worse than gzip.

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For what it's worth: decompression is significantly faster for tar.gz vs. tar.xz. Decompressing the xz utils themselves takes an ~0.083s for tar.gz and ~0.280s for tar.gz (pure user time) on my PC. Compression times are also significantly worse than gz (and even bzip2!). And with the tendency towards high-bandwidth connections, those tend to raise in priority compared to pure compression ratio. –  Joachim Sauer Jun 27 '11 at 13:11
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But xz compression ratio is so much nicer. If you want speed though, lzo is the choice. That said, some Linux distros use only xz -2 to compress e.g. RPMs, as they have determined -9 really is not worth their time. –  jørgensen Dec 24 '11 at 3:23

4 Answers 4

up vote 19 down vote accepted

"Lowest Common Denominator". The extra space saved is rarely worth the interoperability. Most embedded Linux systems have gzip, but not xz. Many old system as well. Gnu Tar which is the industry standard supports flags -z to process through gzip, and -j to process through bzip2, but some old systems don't support the -J flag for xz, meaning it requires 2-step operation (and a lot of extra diskspace for uncompressed .tar unless you use the syntax of |tar xf - - which many people don't know about. Also, uncompressing the full filesystem of some 10MB from tar.gz on embedded ARM takes some 2 minutes and isn't really a problem. No clue about xz but bzip2 takes around 10-15 minutes. Definitely not worth the bandwidth saved.

Anyway, the current "modern alternative" where you sacrifice CPU power in favor of disk space (...which is still rarely a welcome trade - bandwidth and diskspace are cheap, and people hate when systems grind to a halt due to some updates running in background) - is bzip2.

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I can decompress xz archives with tar xvf archive.tar.xz just fine here. –  Artefact2 Jun 27 '11 at 13:30
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@SF: while your conclusion might have been valid Jun 2011, I would hardly call bzip2 the "modern alternative" presently. xz is the "modern alternative", for when you previously would compress with bzip2. I believe even xz with a very low profile, -1 - -3, performs faster and compresses better, when compared to bzip2. Check around the `net for published stats, if one is so inclined. –  TechZilla Jan 21 '13 at 18:26
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Modern versions of tar support the uppercase "J" as xz flag: linux.die.net/man/1/tar –  Diego May 14 '13 at 14:38
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xz is much faster than bzip2 in decompression: lists.fedoraproject.org/pipermail/infrastructure/2010-August/… –  Diego May 14 '13 at 14:40
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Linux Kernels Archive has now dumped bz2 for xz completely: kernel.org/happy-new-year-and-good-bye-bzip2.html but gz continues to be available! –  aalaap Dec 28 '13 at 5:22

The ultimate answer is accessibility, with a secondary answer of purpose. Reasons why XZ is not necessarily as suitable as Gzip:

  • Embedded and legacy systems are far more likely to lack sufficient available memory to decompress LZMA/LZMA2 archives such as XZ. As an example, if XZ can shave 400 KiB (vs. Gzip) off of a package destined for an OpenWrt router, what good is the minor space savings if the router has 16 MiB of RAM? A similar situation appears with very old computer systems. One might scoff at the thought of downloading and compiling the latest version of Bash on an ancient SparcStation LX with 32MB of RAM, but it happens.

  • Such systems usually have slow processors, and decompression time increases can be very high. Three seconds extra to decompress on your Core i5 can be severely long on a 200 MHz ARM core or a 50 MHz microSPARC. Gzip compression is extremely fast on such processors when compared to all better compression methods such as XZ or even Bzip2.

  • Gzip is pretty much universally supported by every UNIX-like system (and nearly every non-UNIX-like system too) created in the past two decades. XZ availability is far more limited. Compression is useless without the ability to decompress it.

  • Higher compression takes a lot of time. If compression time is more important than compression ratio, Gzip beats XZ. Honestly, lzop is much faster than Gzip and still compresses okay, so applications that need the fastest compression possible and don't require Gzip's ubiquity should look at that instead. I routinely shuffle folders quickly across a trusted LAN connection with commands such as "tar -c * | lzop -1 | socat -u - tcp-connect:192.168.0.101:4444" and Gzip could be used similarly over a much slower link (i.e. doing the same thing I just described through an SSH tunnel over the Internet).

Now, on the flip side, there are situations where XZ compression is vastly superior:

  • Sending data over slow links. The Linux 3.7 kernel source code is 34 MiB smaller in XZ format than in Gzip format. If you have a super fast connection, choosing XZ could mean saving one minute of download time; on a cheap DSL connection or a 3G cellular connection, it could shave an hour or more off the download time.

  • Shrinking backup archives. Compressing the source code for Apache's httpd-2.4.2 with "gzip-9" vs. "xz -9e" yields an XZ archive that is 62.7% the size of the Gzip archive. If the same compressibility exists in a data set you currently store as 100 GiB worth of .tar.gz archives, converting to .tar.xz archives would cut a whopping 37.3 GiB off of the backup set. Copying this entire backup data set to a USB 2.0 hard drive (maxing out around 30 MiB/sec transfers) as Gzipped data would take 55 minutes, but XZ compression would make the backup take 20 minutes less. Assuming you'll be working with these backups on a modern desktop system with plenty of CPU power and the one-time-only compression speed isn't a serious problem, using XZ compression generally makes more sense. Why shuffle around extra data if you don't need to?

  • Distributing large amounts of data that might be highly compressible. As previously mentioned, Linux 3.7 source code is 67 MiB for .tar.xz and 101 MiB for .tar.gz; the uncompressed source code is about 542 MiB and is almost entirely text. Source code (and text in general) is typically highly compressible because of the amount of redundancy in the contents, but compressors like Gzip that operate with a much smaller dictionary don't get to take advantage of redundancy that goes beyond their dictionary size.

Ultimately, it all falls back to a four-way tradeoff: compressed size, compression/decompression speed, copying/transmission speed (reading the data from disk/network), and availability of the compressor/decompressor. The selection is highly dependent on the question "what are you planning to do with this data?"

Also check out this related post from which I learned some of the things I repeat here.

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People should tread carefully, if compressing with xz, before setting the -9 profile. This is an except from the xz man page, "The differences between the presets are more significant than with gzip(1) and bzip2(1). The selected compression settings determine the memory requirements of the decompressor, thus using a too high preset level might make it painful to decompress the file on an old system with little RAM. Specifically, it's not a good idea to blindly use -9 for everything like it often is with gzip(1) and bzip2(1)." –  TechZilla Jan 21 '13 at 18:21
    
@TechZilla is definitely correct; the XZ algorithm is very memory-intensive, and one must take into account the decompression target where with other algorithms it might not be a concern. Reading the man pages, one can see a chart listing the dictionary size of each numbered profile; using any number higher than the one whose dictionary size minimally exceeds your total data size gains nothing at all, while significantly increasing decompressor memory usage. For most smaller data sets, xz -2e seems to work well. –  Jody Lee Bruchon Feb 2 '13 at 18:46

For the same reason people in Windows (r) use zip files instead of 7zip, and some still use rar instead of other formats... Or mp3 is used in music, instead of aac+, and so on.

Each format has it's benefits and people use to stick to a solution they learned when began using a computer. Add this to backward compatibility and fast bandwidth + GB or TB of space in hard drives, and the benefits of a greater compression won't be that relevant.

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But internet links don't grow as fast as hard disks... –  jørgensen Dec 24 '11 at 3:24
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Yea I've heard that line at work before also... "but the storage is so cheep yadda yadda"..."Who cares if we piss away oodles of space".. But even if you believe that, and don't value things like a quick backup, bandwidth is indeed a completely different animal. Especially if you're serving a huge tarball to countless downloaders. –  TechZilla Jan 25 at 1:06

Honestly, I just get to know .xz format from a training material. So I just used its git repo to do a test. The git is git://git.free-electrons.com/training-materials.git, and I also compiled the three training slides. The total directory size is 91M, with a mixture of text and binary data.

Here is my quick result. Maybe people still favor tar.gz simply because it's much faster to compress? I personally even use plain tar when there aren't many benefits to be gained in compression.

[02:49:32]wujj@WuJJ-PC-Linux /tmp $ time tar czf test.tgz training-materials/

real    0m3.371s
user    0m3.208s
sys     0m0.128s
[02:49:46]wujj@WuJJ-PC-Linux /tmp $ time tar cJf test.txz training-materials/

real    0m34.557s
user    0m33.930s
sys     0m0.372s
[02:50:31]wujj@WuJJ-PC-Linux /tmp $ time tar cf test.tar training-materials/

real    0m0.117s
user    0m0.020s
sys     0m0.092s
[02:51:03]wujj@WuJJ-PC-Linux /tmp $ ll test*
-rw-rw-r-- 1 wujj wujj 91944960 2012-07-09 02:51 test.tar
-rw-rw-r-- 1 wujj wujj 69042586 2012-07-09 02:49 test.tgz
-rw-rw-r-- 1 wujj wujj 60609224 2012-07-09 02:50 test.txz
[02:56:03]wujj@WuJJ-PC-Linux /tmp $ time tar xzf test.tgz

real    0m0.719s
user    0m0.536s
sys     0m0.144s
[02:56:24]wujj@WuJJ-PC-Linux /tmp $ time tar xf test.tar

real    0m0.189s
user    0m0.004s
sys     0m0.108s
[02:56:33]wujj@WuJJ-PC-Linux /tmp $ time tar xJf test.txz

real    0m3.116s
user    0m2.612s
sys     0m0.184s
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